import * as THREE from  '../three.module.js'
var BACK, COPLANAR, EPSILON, FRONT, SPANNING, returning,
    __bind = function(fn, me){ return function(){ return fn.apply(me, arguments); }; },
    __slice = [].slice,
    __hasProp = {}.hasOwnProperty,
    __extends = function(child, parent) { for (var key in parent) { if (__hasProp.call(parent, key)) child[key] = parent[key]; } function ctor() { this.constructor = child; } ctor.prototype = parent.prototype; child.prototype = new ctor(); child.__super__ = parent.prototype; return child; };

EPSILON = 1e-5;

COPLANAR = 0;

FRONT = 1;

BACK = 2;

SPANNING = 3;

returning = function(value, fn) {
    fn();
    return value;
};

const ThreeBSP = (function() {
    function ThreeBSP(treeIsh, matrix) {
        this.matrix = matrix;
        this.intersect = __bind(this.intersect, this);
        this.union = __bind(this.union, this);
        this.subtract = __bind(this.subtract, this);
        this.toGeometry = __bind(this.toGeometry, this);
        this.toMesh = __bind(this.toMesh, this);
        this.toTree = __bind(this.toTree, this);
        if (this.matrix == null) {
            this.matrix = new THREE.Matrix4();
        }
        this.tree = this.toTree(treeIsh);
    }

    ThreeBSP.prototype.toTree = function(treeIsh) {
        var face, geometry, i, polygons, _fn, _i, _len, _ref,
            _this = this;
        if (treeIsh instanceof ThreeBSP.Node) {
            return treeIsh;
        }
        polygons = [];
        geometry = treeIsh instanceof THREE.Geometry ? treeIsh : treeIsh instanceof THREE.Mesh ? (treeIsh.updateMatrix(), this.matrix = treeIsh.matrix.clone(), treeIsh.geometry) : void 0;
        _ref = geometry.faces;
        _fn = function(face, i) {
            var faceVertexUvs, idx, polygon, vIndex, vName, vertex, _j, _len1, _ref1, _ref2;
            faceVertexUvs = (_ref1 = geometry.faceVertexUvs) != null ? _ref1[0][i] : void 0;
            if (faceVertexUvs == null) {
                faceVertexUvs = [new THREE.Vector2(), new THREE.Vector2(), new THREE.Vector2(), new THREE.Vector2()];
            }
            polygon = new ThreeBSP.Polygon();
            _ref2 = ['a', 'b', 'c', 'd'];
            for (vIndex = _j = 0, _len1 = _ref2.length; _j < _len1; vIndex = ++_j) {
                vName = _ref2[vIndex];
                if ((idx = face[vName]) != null) {
                    vertex = geometry.vertices[idx];
                    vertex = new ThreeBSP.Vertex(vertex.x, vertex.y, vertex.z, face.vertexNormals[0], new THREE.Vector2(faceVertexUvs[vIndex].x, faceVertexUvs[vIndex].y));
                    vertex.applyMatrix4(_this.matrix);
                    polygon.vertices.push(vertex);
                }
            }
            return polygons.push(polygon.calculateProperties());
        };
        for (i = _i = 0, _len = _ref.length; _i < _len; i = ++_i) {
            face = _ref[i];
            _fn(face, i);
        }
        return new ThreeBSP.Node(polygons);
    };

    ThreeBSP.prototype.toMesh = function(material) {
        var geometry, mesh,
            _this = this;
        if (material == null) {
            material = new THREE.MeshNormalMaterial();
        }
        geometry = this.toGeometry();
        return returning((mesh = new THREE.Mesh(geometry, material)), function() {
            mesh.position.setFromMatrixPosition(_this.matrix);
            return mesh.rotation.setFromRotationMatrix(_this.matrix);
        });
    };

    ThreeBSP.prototype.toGeometry = function() {
        var geometry, matrix,
            _this = this;
        matrix = new THREE.Matrix4().getInverse(this.matrix);
        return returning((geometry = new THREE.Geometry()), function() {
            var face, idx, polyVerts, polygon, v, vertUvs, verts, _i, _len, _ref, _results;
            _ref = _this.tree.allPolygons();
            _results = [];
            for (_i = 0, _len = _ref.length; _i < _len; _i++) {
                polygon = _ref[_i];
                polyVerts = (function() {
                    var _j, _len1, _ref1, _results1;
                    _ref1 = polygon.vertices;
                    _results1 = [];
                    for (_j = 0, _len1 = _ref1.length; _j < _len1; _j++) {
                        v = _ref1[_j];
                        _results1.push(v.clone().applyMatrix4(matrix));
                    }
                    return _results1;
                })();
                _results.push((function() {
                    var _j, _ref1, _results1;
                    _results1 = [];
                    for (idx = _j = 2, _ref1 = polyVerts.length; 2 <= _ref1 ? _j < _ref1 : _j > _ref1; idx = 2 <= _ref1 ? ++_j : --_j) {
                        verts = [polyVerts[0], polyVerts[idx - 1], polyVerts[idx]];
                        vertUvs = (function() {
                            var _k, _len1, _ref2, _ref3, _results2;
                            _results2 = [];
                            for (_k = 0, _len1 = verts.length; _k < _len1; _k++) {
                                v = verts[_k];
                                _results2.push(new THREE.Vector2((_ref2 = v.uv) != null ? _ref2.x : void 0, (_ref3 = v.uv) != null ? _ref3.y : void 0));
                            }
                            return _results2;
                        })();
                        face = (function(func, args, ctor) {
                            ctor.prototype = func.prototype;
                            var child = new ctor, result = func.apply(child, args);
                            return Object(result) === result ? result : child;
                        })(THREE.Face3, __slice.call((function() {
                            var _k, _len1, _results2;
                            _results2 = [];
                            for (_k = 0, _len1 = verts.length; _k < _len1; _k++) {
                                v = verts[_k];
                                _results2.push(geometry.vertices.push(v) - 1);
                            }
                            return _results2;
                        })()).concat([polygon.normal.clone()]), function(){});
                        geometry.faces.push(face);
                        _results1.push(geometry.faceVertexUvs[0].push(vertUvs));
                    }
                    return _results1;
                })());
            }
            return _results;
        });
    };

    ThreeBSP.prototype.subtract = function(other) {
        var them, us, _ref;
        _ref = [this.tree.clone(), other.tree.clone()], us = _ref[0], them = _ref[1];
        us.invert().clipTo(them);
        them.clipTo(us).invert().clipTo(us).invert();
        return new ThreeBSP(us.build(them.allPolygons()).invert(), this.matrix);
    };

    ThreeBSP.prototype.union = function(other) {
        var them, us, _ref;
        _ref = [this.tree.clone(), other.tree.clone()], us = _ref[0], them = _ref[1];
        us.clipTo(them);
        them.clipTo(us).invert().clipTo(us).invert();
        return new ThreeBSP(us.build(them.allPolygons()), this.matrix);
    };

    ThreeBSP.prototype.intersect = function(other) {
        var them, us, _ref;
        _ref = [this.tree.clone(), other.tree.clone()], us = _ref[0], them = _ref[1];
        them.clipTo(us.invert()).invert().clipTo(us.clipTo(them));
        return new ThreeBSP(us.build(them.allPolygons()).invert(), this.matrix);
    };

    return ThreeBSP;

})();

ThreeBSP.Vertex = (function(_super) {
    __extends(Vertex, _super);

    function Vertex(x, y, z, normal, uv) {
        this.normal = normal != null ? normal : new THREE.Vector3();
        this.uv = uv != null ? uv : new THREE.Vector2();
        this.interpolate = __bind(this.interpolate, this);
        this.lerp = __bind(this.lerp, this);
        Vertex.__super__.constructor.call(this, x, y, z);
    }

    Vertex.prototype.clone = function() {
        return new ThreeBSP.Vertex(this.x, this.y, this.z, this.normal.clone(), this.uv.clone());
    };

    Vertex.prototype.lerp = function(v, alpha) {
        var _this = this;
        return returning(Vertex.__super__.lerp.apply(this, arguments), function() {
            _this.uv.add(v.uv.clone().sub(_this.uv).multiplyScalar(alpha));
            return _this.normal.lerp(v, alpha);
        });
    };

    Vertex.prototype.interpolate = function() {
        var args, _ref;
        args = 1 <= arguments.length ? __slice.call(arguments, 0) : [];
        return (_ref = this.clone()).lerp.apply(_ref, args);
    };

    return Vertex;

})(THREE.Vector3);

ThreeBSP.Polygon = (function() {
    function Polygon(vertices, normal, w) {
        this.vertices = vertices != null ? vertices : [];
        this.normal = normal;
        this.w = w;
        this.subdivide = __bind(this.subdivide, this);
        this.tessellate = __bind(this.tessellate, this);
        this.classifySide = __bind(this.classifySide, this);
        this.classifyVertex = __bind(this.classifyVertex, this);
        this.invert = __bind(this.invert, this);
        this.clone = __bind(this.clone, this);
        this.calculateProperties = __bind(this.calculateProperties, this);
        if (this.vertices.length) {
            this.calculateProperties();
        }
    }

    Polygon.prototype.calculateProperties = function() {
        var _this = this;
        return returning(this, function() {
            var a, b, c, _ref;
            _ref = _this.vertices, a = _ref[0], b = _ref[1], c = _ref[2];
            _this.normal = b.clone().sub(a).cross(c.clone().sub(a)).normalize();
            return _this.w = _this.normal.clone().dot(a);
        });
    };

    Polygon.prototype.clone = function() {
        var v;
        return new ThreeBSP.Polygon((function() {
            var _i, _len, _ref, _results;
            _ref = this.vertices;
            _results = [];
            for (_i = 0, _len = _ref.length; _i < _len; _i++) {
                v = _ref[_i];
                _results.push(v.clone());
            }
            return _results;
        }).call(this), this.normal.clone(), this.w);
    };

    Polygon.prototype.invert = function() {
        var _this = this;
        return returning(this, function() {
            _this.normal.multiplyScalar(-1);
            _this.w *= -1;
            return _this.vertices.reverse();
        });
    };

    Polygon.prototype.classifyVertex = function(vertex) {
        var side;
        side = this.normal.dot(vertex) - this.w;
        switch (false) {
            case !(side < -EPSILON):
                return BACK;
            case !(side > EPSILON):
                return FRONT;
            default:
                return COPLANAR;
        }
    };

    Polygon.prototype.classifySide = function(polygon) {
        var back, front, tally, v, _i, _len, _ref, _ref1,
            _this = this;
        _ref = [0, 0], front = _ref[0], back = _ref[1];
        tally = function(v) {
            switch (_this.classifyVertex(v)) {
                case FRONT:
                    return front += 1;
                case BACK:
                    return back += 1;
            }
        };
        _ref1 = polygon.vertices;
        for (_i = 0, _len = _ref1.length; _i < _len; _i++) {
            v = _ref1[_i];
            tally(v);
        }
        if (front > 0 && back === 0) {
            return FRONT;
        }
        if (front === 0 && back > 0) {
            return BACK;
        }
        if ((front === back && back === 0)) {
            return COPLANAR;
        }
        return SPANNING;
    };

    Polygon.prototype.tessellate = function(poly) {
        var b, count, f, i, j, polys, t, ti, tj, v, vi, vj, _i, _len, _ref, _ref1, _ref2,
            _this = this;
        _ref = {
            f: [],
            b: [],
            count: poly.vertices.length
        }, f = _ref.f, b = _ref.b, count = _ref.count;
        if (this.classifySide(poly) !== SPANNING) {
            return [poly];
        }
        _ref1 = poly.vertices;
        for (i = _i = 0, _len = _ref1.length; _i < _len; i = ++_i) {
            vi = _ref1[i];
            vj = poly.vertices[(j = (i + 1) % count)];
            _ref2 = (function() {
                var _j, _len1, _ref2, _results;
                _ref2 = [vi, vj];
                _results = [];
                for (_j = 0, _len1 = _ref2.length; _j < _len1; _j++) {
                    v = _ref2[_j];
                    _results.push(this.classifyVertex(v));
                }
                return _results;
            }).call(this), ti = _ref2[0], tj = _ref2[1];
            if (ti !== BACK) {
                f.push(vi);
            }
            if (ti !== FRONT) {
                b.push(vi);
            }
            if ((ti | tj) === SPANNING) {
                t = (this.w - this.normal.dot(vi)) / this.normal.dot(vj.clone().sub(vi));
                v = vi.interpolate(vj, t);
                f.push(v);
                b.push(v);
            }
        }
        return returning((polys = []), function() {
            if (f.length >= 3) {
                polys.push(new ThreeBSP.Polygon(f));
            }
            if (b.length >= 3) {
                return polys.push(new ThreeBSP.Polygon(b));
            }
        });
    };

    Polygon.prototype.subdivide = function(polygon, coplanar_front, coplanar_back, front, back) {
        var poly, side, _i, _len, _ref, _results;
        _ref = this.tessellate(polygon);
        _results = [];
        for (_i = 0, _len = _ref.length; _i < _len; _i++) {
            poly = _ref[_i];
            side = this.classifySide(poly);
            switch (side) {
                case FRONT:
                    _results.push(front.push(poly));
                    break;
                case BACK:
                    _results.push(back.push(poly));
                    break;
                case COPLANAR:
                    if (this.normal.dot(poly.normal) > 0) {
                        _results.push(coplanar_front.push(poly));
                    } else {
                        _results.push(coplanar_back.push(poly));
                    }
                    break;
                default:
                    throw new Error("BUG: Polygon of classification " + side + " in subdivision");
            }
        }
        return _results;
    };

    return Polygon;

})();

ThreeBSP.Node = (function() {
    Node.prototype.clone = function() {
        var node,
            _this = this;
        return returning((node = new ThreeBSP.Node()), function() {
            var p, _ref, _ref1, _ref2;
            node.divider = (_ref = _this.divider) != null ? _ref.clone() : void 0;
            node.polygons = (function() {
                var _i, _len, _ref1, _results;
                _ref1 = this.polygons;
                _results = [];
                for (_i = 0, _len = _ref1.length; _i < _len; _i++) {
                    p = _ref1[_i];
                    _results.push(p.clone());
                }
                return _results;
            }).call(_this);
            node.front = (_ref1 = _this.front) != null ? _ref1.clone() : void 0;
            return node.back = (_ref2 = _this.back) != null ? _ref2.clone() : void 0;
        });
    };

    function Node(polygons) {
        this.clipTo = __bind(this.clipTo, this);
        this.clipPolygons = __bind(this.clipPolygons, this);
        this.invert = __bind(this.invert, this);
        this.allPolygons = __bind(this.allPolygons, this);
        this.isConvex = __bind(this.isConvex, this);
        this.build = __bind(this.build, this);
        this.clone = __bind(this.clone, this);
        this.polygons = [];
        if ((polygons != null) && polygons.length) {
            this.build(polygons);
        }
    }

    Node.prototype.build = function(polygons) {
        var _this = this;
        return returning(this, function() {
            var poly, polys, side, sides, _i, _len, _results;
            sides = {
                front: [],
                back: []
            };
            if (_this.divider == null) {
                _this.divider = polygons[0].clone();
            }
            for (_i = 0, _len = polygons.length; _i < _len; _i++) {
                poly = polygons[_i];
                _this.divider.subdivide(poly, _this.polygons, _this.polygons, sides.front, sides.back);
            }
            _results = [];
            for (side in sides) {
                if (!__hasProp.call(sides, side)) continue;
                polys = sides[side];
                if (polys.length) {
                    if (_this[side] == null) {
                        _this[side] = new ThreeBSP.Node();
                    }
                    _results.push(_this[side].build(polys));
                } else {
                    _results.push(void 0);
                }
            }
            return _results;
        });
    };

    Node.prototype.isConvex = function(polys) {
        var inner, outer, _i, _j, _len, _len1;
        for (_i = 0, _len = polys.length; _i < _len; _i++) {
            inner = polys[_i];
            for (_j = 0, _len1 = polys.length; _j < _len1; _j++) {
                outer = polys[_j];
                if (inner !== outer && outer.classifySide(inner) !== BACK) {
                    return false;
                }
            }
        }
        return true;
    };

    Node.prototype.allPolygons = function() {
        var _ref, _ref1;
        return this.polygons.slice().concat(((_ref1 = this.front) != null ? _ref1.allPolygons() : void 0) || []).concat(((_ref = this.back) != null ? _ref.allPolygons() : void 0) || []);
    };

    Node.prototype.invert = function() {
        var _this = this;
        return returning(this, function() {
            var flipper, poly, _i, _j, _len, _len1, _ref, _ref1, _ref2;
            _ref = _this.polygons;
            for (_i = 0, _len = _ref.length; _i < _len; _i++) {
                poly = _ref[_i];
                poly.invert();
            }
            _ref1 = [_this.divider, _this.front, _this.back];
            for (_j = 0, _len1 = _ref1.length; _j < _len1; _j++) {
                flipper = _ref1[_j];
                if (flipper != null) {
                    flipper.invert();
                }
            }
            return _ref2 = [_this.back, _this.front], _this.front = _ref2[0], _this.back = _ref2[1], _ref2;
        });
    };

    Node.prototype.clipPolygons = function(polygons) {
        var back, front, poly, _i, _len;
        if (!this.divider) {
            return polygons.slice();
        }
        front = [];
        back = [];
        for (_i = 0, _len = polygons.length; _i < _len; _i++) {
            poly = polygons[_i];
            this.divider.subdivide(poly, front, back, front, back);
        }
        if (this.front) {
            front = this.front.clipPolygons(front);
        }
        if (this.back) {
            back = this.back.clipPolygons(back);
        }
        return front.concat(this.back ? back : []);
    };

    Node.prototype.clipTo = function(node) {
        var _this = this;
        return returning(this, function() {
            var _ref, _ref1;
            _this.polygons = node.clipPolygons(_this.polygons);
            if ((_ref = _this.front) != null) {
                _ref.clipTo(node);
            }
            return (_ref1 = _this.back) != null ? _ref1.clipTo(node) : void 0;
        });
    };

    return Node;

})();

export {
    ThreeBSP
}
